KR200380793Y1 - Sealing Structure for Shaft of Chest Agitator - Google Patents

Abstract

In order to increase the sealing effect, improve durability and maintain a continuous sealing effect, a stuffing box, a first flange assembled to the stuffing box, a teflon ring installed close to the first flange, and a teflon ring are prepared. A second flange closely attached to and supported by the first flange, a third flange installed at a predetermined distance from the second flange, and a third flange installed between the third flange and the second flange in a direction in which the second flange is in close contact with the Teflon ring. Provided is a sealing structure for the stirrer shaft including a spring for applying a force to the two flanges.

Description

Sealing Structure for Shaft of Chest Agitator

The present invention relates to a sealing structure for the stirrer shaft, and more particularly to a stirrer shaft sealing structure in which durability is improved even when rotational friction occurs using a Teflon ring to maintain the sealing effect for a long time.

In general, agitators (chest agitator) for agitating the raw material is used a lot.

The agitator is provided with a shaft inside the tank, and the stirring blade is attached to the shaft. The shaft of the stirrer connected to the rotary power source installed outside of the tank is rotatably supported without leakage of the raw material stirred in the tank through a packing box called a stuffing box.

Grand packing is mainly used for the stuffing box, and direct rotational friction is generated between the sleeve and the grand packing which rotate together with the stirrer shaft.

When friction occurs as described above, a gap is generated by abrasion of the sleeve serving as a seal, and leakage of raw material subjected to hydraulic pressure occurs through this gap.

In addition, even in the case of overtightening a grand by using a grand bolt, the grand packing is easily damaged by the uneven portion of the worn surface of the sleeve, and leakage of raw materials continues to occur.

In addition, as the gland packing is used, the water for cooling the frictional heat must be supplied into the stuffing box. Therefore, the structure of the stuffing box is complicated due to the formation of the cooling flow path, and there is a problem in that water consumption is increased by using the water.

An object of the present invention is to solve the above problems, by using a Teflon ring (Teflon ring) to increase the sealing effect and to improve the durability and to use the spring sealing structure for the stirrer shaft to obtain a continuous sealing effect It is to provide.

The present invention proposes a sealing structure for an agitator shaft comprising a stuffing box, a first flange assembled to the stuffing box, a Teflon ring tightly installed on the first flange, and the Teflon ring. A second flange that is in close contact with the first flange, a third flange that is installed at a predetermined distance from the second flange, and is installed between the third flange and the second flange and is in close contact with the Teflon ring. It includes a spring for applying a force to the second flange in the direction.

Next, a preferred embodiment of the sealing structure for the stirrer shaft according to the present invention will be described in detail with reference to the drawings.

First, an embodiment of the sealing structure for the agitator shaft according to the present invention, as shown in Figure 1 and 2, the stuffing box 10, the first flange 20 is assembled to the stuffing box 10, and the first Teflon ring 30 which is installed in close contact with the first flange 20, a second flange 40 that closely supports the Teflon ring 30 between the first flange 20, and the second flange 40. The third flange 50 is installed at a predetermined interval from the, and the second flange in a direction in which it is installed between the third flange 50 and the second flange 40 in close contact with the Teflon ring 30 It comprises a spring 60 for applying a force to the 40.

The stuffing box 10 is formed in a cylindrical shape, the inner surface is installed in contact with the sleeve (4) installed on the stirrer shaft (2).

A flange portion 11 is formed at the side on which the first flange 20 of the stuffing box 10 is assembled, and is formed in a conical shape inclined from the flange portion 11 to the opposite side of the first flange 20.

The stuffing box 10 can be implemented by applying the configuration of the stuffing box (stuffing box) that is generally used in rotary devices such as pumps, motors, stirrers, etc., except for the above configuration, a detailed description thereof will be omitted.

It is preferable to insert a gasket 28 between the first flange 20 and the Teflon ring 30 to prevent leakage of raw materials.

The first flange 20 is formed by coating a ceramic in a disk ring shape made of stainless steel.

The first flange 20 is fixed to the stuffing box 10 using a fixing bolt 28 or the like.

The first flange 20 forms a bolt hole 24 into which the fixing bolt 28 is inserted.

The teflon ring 30 has a cylindrical shape, and is provided with two to four O-rings 34 at predetermined intervals on an inner surface thereof, between the stirrer shaft 2 or the sleeve 4 and the teflon ring 30. It is desirable to prevent the raw material from leaking.

An inner surface of the Teflon ring 30 forms a ring groove 32 for installing the O-ring 34.

The teflon ring 30 is fixed to the second flange 40 through a bolt 38 or the like so as to rotate together when the stirrer shaft 2 rotates.

One side of the Teflon ring 30 forms a fastening hole 34 to which the bolt 38 is fastened.

The second flange 40 is formed in a disc ring shape.

One end surface of the second flange 40 is formed with an assembly groove 46 into which a part of the end portion of the teflon ring 30 is inserted.

The third flange 50 is fixedly installed through a stud bolt 58 or the like so as to rotate together with the stirrer shaft 2.

The third flange 50 is formed so that the cross-sectional shape is formed in a substantially "L" shape consisting of the flange portion 51 and the cylindrical portion 52, the cylindrical portion 52 for inserting the stud bolt 58 The fixing hole 53 is formed.

2 to 3 for adjusting the tension of the spring 60 applied to the second flange 40 by supporting the spring 60 and adjusting an interval between the second flange 40 and the third flange 50. Six set screws 48 are installed.

In the flange portion 51 of the second flange 40 and the third flange 50, screw holes 44 and 54 for inserting the set screw 48 are formed, respectively.

A nut 49 is fastened to the set screw 48.

When the tension (elastic force) of the spring 60 to closely contact the second flange 40 toward the Teflon ring 30 acts excessively, the wear of the Teflon ring 30 is excessive, and the tension (elastic force) is too small. There is a risk of raw material leakage.

Therefore, it is preferable to adjust the set screw 48 to adjust the tension of the spring 60, and maintain the tension of the spring 60 properly according to the wear of the Teflon ring 30.

In the above, a preferred embodiment of the sealing structure for the agitator shaft according to the present invention has been described, but the present invention is not limited thereto, and the present invention is not limited thereto. It is possible and this also belongs to the scope of the present invention.

According to the sealing structure for the stirrer shaft according to the present invention made as described above, by using the Teflon ring, the sealing effect is greatly improved and the service life of the sleeve is increased. That is, even if a flaw occurs in the sleeve, since the sealing is completely made by the Teflon ring, the sleeve does not need to be replaced immediately, and thus it can be used semi-permanently.

And as the Teflon ring is worn, it is possible to maintain a constant sealing state by adjusting the tension of the spring at all times, so that it is possible to effectively prevent the leakage of raw materials and to reduce the maintenance cost.

In addition, according to the sealing structure for the stirrer shaft according to the present invention, since the sealing effect is sufficiently obtained without using the grand packing, it is possible to reduce the purchase cost of the grand packing. Furthermore, since the grand packing is not used, it is not necessary to use the water for cooling required when the grand packing is used, so that maintenance costs can be reduced and water consumption can be reduced.

1 is a perspective view showing an embodiment of the sealing structure for the stirrer shaft according to the present invention.

2 is a cross-sectional view showing an embodiment of the sealing structure for the stirrer shaft according to the present invention.

Claims (5)

Stuffing box, A first flange assembled to the stuffing box, Cylindrical teflon ring which is installed in close contact with the first flange, A second flange for tightly supporting the teflon ring between the first flange and the second flange; A third flange installed at a predetermined interval from the second flange, And a spring installed between the third flange and the second flange and applying a force to the second flange in a direction in close contact with the teflon ring. The method according to claim 1, Sealing structure for the stirrer shaft for inserting a gasket between the first flange and the Teflon ring. The method according to claim 1 or 2, The first flange is made by coating a ceramic on a disk ring shape made of stainless steel, The first flange is fixed to the stuffing box using a fixing bolt fixed structure for the agitator shaft. The method according to claim 1 or 2, The Teflon ring is provided with two to four O-rings at predetermined intervals on the inner surface, The teflon ring is fixed to the second flange through a bolt, One end surface of the second flange forms an assembly groove into which a part of the end portion of the teflon ring is inserted, The third flange is a stirrer shaft sealing structure that is fixed through the stud bolt to rotate with the stirrer shaft. The method according to claim 4, A stirrer shaft sealing structure between the second flange and the third flange to support the spring and to adjust the spacing to install two to six set screws for adjusting the tension of the spring applied to the second flange.